Methods and apparatus in a wireless communication system for transmitting and receiving user data on a carrier

ABSTRACT

A base station is configured to transmit user data to a wireless device upon a first carrier. The base station identifies, from a set of transmission resources that is nominally allocated for transmission of user data upon the first carrier, a subset of transmission resources that is also nominally allocated for transmission of a reference or control signal either by the base station upon a second carrier or by a neighboring base station upon the first carrier. The base station selectively transmits user data to the wireless device upon the first carrier exclusive of this identified subset of transmission resources. The device in some embodiments obtains information indicating that the base station is selectively transmitting user data upon the first carrier exclusive of the subset in this way. Based on this information, the device recovers user data received upon the first carrier exclusive of the subset of transmission resources.

RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 14/386,520, filed Sep. 19, 2014, now granted as U.S. Pat. No.10,448,396 on Oct. 15, 2019, which is a national stage application ofInternational Patent Application No. PCT/SE2013/050299, filed Mar. 19,2013, which claims priority to U.S. Provisional Patent Application Ser.No. 61/612,733, which was filed Mar. 19, 2012 and are incorporatedherein in their entirety by reference.

TECHNICAL FIELD

The present application generally relates to a wireless communicationsystem, and particularly relates to user data being transmitted betweena base station and a wireless device upon a first carrier in thewireless communication system.

BACKGROUND

Long Term Evolution (LTE) uses Orthogonal Frequency DivisionMultiplexing (OFDM) in the downlink and Discrete Fourier Transform(DFT)-spread OFDM in the uplink. The basic LTE downlink physicalresource can thus be seen as a time-frequency grid as illustrated inFIG. 1, where each resource element (RE) corresponds to one OFDMsubcarrier during one OFDM symbol interval.

In the time domain, LTE downlink transmissions are organized into radioframes of 10 ms, as shown in FIG. 2. Each radio frame consists of tenequally-sized subframes of length Tsubframe=1 ms.

Furthermore, the resource allocation in LTE is typically described interms of resource blocks (RB), where a resource block corresponds to oneslot (0.5 ms) in the time domain and 12 contiguous subcarriers in thefrequency domain. A pair of two adjacent resource blocks in timedirection (1.0 ms) is known as a resource block pair. Resource blocksare numbered in the frequency domain, starting with 0 from one end ofthe system bandwidth.

The notion of virtual resource blocks (VRB) and physical resource blocks(PRB) has been introduced in LTE. The actual resource allocation to a UEis made in terms of VRB pairs. There are two types of resourceallocations, localized and distributed. In the localized resourceallocation, a VRB pair is directly mapped to a PRB pair, hence twoconsecutive and localized VRB are also placed as consecutive PRBs in thefrequency domain. On the other hand, the distributed VRBs are not mappedto consecutive PRBs in the frequency domain, thereby providing frequencydiversity for data channel transmitted using these distributed VRBs.

Downlink transmissions are dynamically scheduled, i.e., in each subframethe base station transmits control information about to which terminalsdata is transmitted and upon which resource blocks the data istransmitted, in the current downlink subframe. This control signaling istypically transmitted in the first 1, 2, 3 or 4 OFDM symbols in eachsubframe and the number n=1, 2, 3 or 4 is known as the Control FormatIndicator (CFI). The downlink subframe also contains common referencesymbols (CRS), which are known to the receiver and used for coherentdemodulation of e.g. the control information. A downlink system withCFI=3 OFDM symbols as control is illustrated in FIG. 3.

The LTE Rel-10 specifications have recently been standardized,supporting Component Carrier (CC) bandwidths up to 20 MHz, which is themaximal LTE Rel-8 carrier bandwidth. Hence, an LTE Rel-10 operationwider than 20 MHz is possible and appear as a number of LTE carriers toan LTE Rel-10 terminal.

In particular for early LTE Rel-10 deployments it can be expected thatthere will be a smaller number of LTE Rel-10-capable terminals (i.e.,non-legacy terminals) compared to many LTE legacy terminals. Therefore,it is necessary to assure an efficient use of a wide carrier also forlegacy terminals, i.e. that it is possible to implement carriers wherelegacy terminals can be scheduled in all parts of the wideband LTERel-10 carrier. The straightforward way to obtain this would be by meansof Carrier Aggregation (CA). CA implies that an LTE Rel-10 terminal canreceive multiple CC, where the CC have, or at least has the possibilityto have, the same structure as a Rel-8 carrier. CA is illustrated inFIG. 4.

The Rel-10 standard supports up to 5 aggregated carriers where eachcarrier is limited in the RF specifications to have one of sixbandwidths namely 6, 15, 25, 50, 75 or 100 RB, corresponding to 1.4, 3 510 15 and 20 MHz respectively.

The number of aggregated CC as well as the bandwidth of the individualCC may be different for uplink and downlink. A symmetric configurationrefers to the case where the number of CCs in downlink and uplink is thesame whereas an asymmetric configuration refers to the case that thenumber of CCs is different. It is important to note that the number ofCCs configured in the network may be different from the number of CCsseen by a terminal: A terminal may for example support more downlink CCsthan uplink CCs, even though the network offers the same number ofuplink and downlink CCs.

During initial access a LTE Rel-10 terminal behaves similar to a LTERel-8 terminal. Upon successful connection to the network a terminalmay—depending on its own capabilities and the network—be configured withadditional CCs in the UL and DL. Configuration is based on RadioResource Control (RRC). Due to the heavy signaling and rather slow speedof RRC signaling it is envisioned that a terminal may be configured withmultiple CCs even though not all of them are currently used. If aterminal is activated on multiple CCs this would imply it has to monitorall downlink (DL) CCs for Physical Downlink Control Channel (PDCCH) andPhysical Downlink Shared Channel (PDSCH). This implies a wider receiverbandwidth, higher sampling rates, etc. resulting in high powerconsumption.

Two types of carriers are referred to herein. The first type of carrieris a Rel-8 backward compatible carrier. It is characterized by thatRel-8, Rel-9 and Rel-10 User Equipment (UE) can operate on it. Forsimplicity it is referred to as carrier type A.

The second carrier type is described as a carrier type that containseither no CRS at all or much less CRS either in frequency, by forexample a reduction of the bandwidth the CRS covers to be smaller thanthe carrier bandwidth, or in time, by for example not transmitting anyCRS in some pre-defined subframes, or in both frequency and timecompared to a type A carrier. It further may not contain any PDCCH butonly the enhanced Control Channels eCCH including the enhanced PDCCH(ePDCCH) and/or the enhanced Physical Hybrid Automatic RetransmissionreQuest (HARQ) Indicator Channel (ePHICH), which do not rely on CRS fordemodulation. This type of carrier is referred to as carrier type B.Carrier type B is attractive for its energy efficiency properties, itslow control and reference signal overhead and low level of interferencegeneration in networks when compared to carrier type A.

The lack of CRS and/or PDCCH, PHICH, PCFICH will make this type ofcarrier, i.e., carrier type B, not accessible by legacy release UEs whendeployed, i.e. it is not backwards compatible. Carrier type A andcarrier type B are illustrated in FIG. 5 and FIG. 6 respectively.

The definition of the fields used in FIG. 5 are shown in FIG. 5 only andwill be used also in relation to other figures herein even if left outfrom those figures. More specifically, FIG. 5 shows carrier type A intime (along the horizontal axis) and in frequency (along the verticalaxis). FIG. 5 shows the carrier structured in time as 5 differentsubframes. In general, the Physical Control Format IndicatorChannel/Physical Downlink Control Channel/Physical Hybrid ARQ IndicatorChannel (PCFICH/PDCCH/PHICH) occupies the beginning of each subframeacross the carrier bandwidth, and the PDSCH (including the ePDCCH)occupies the rest of each subframe. That said, the CRS is transmitted ina pattern across the carrier, and in FIG. 5 shows up as “dots”distributed over the figure. By contrast, FIG. 6 shows that carrier typeB does not transmit the PCFICH/PDCCH/PHICH, and only transmits CRSwithin the second subframe and across a portion of the carrier bandwidth(outlined as a rectangle within the second subframe). In both FIGS. 5and 6, the Physical Broadcast Channel/Primary SynchronizationSignal/Secondary Synchronization Signal (PBCH/PSS/SSS) is transmittedwithin this rectangle, after the PCFICH/PDCCH/PHICH (in FIG. 5).

Carrier type B can only be accessible by terminals of the new releaseand not of legacy releases as it is non-backward compatible. At the timewhen carrier type B will be deployed in networks there will only belimited set of such new release terminals available that has thecapability to access it and receive data on it. At the same time therewill be a large population of legacy release terminals operating inexisting networks, i.e. terminals only capable of accessing carriers oftype A.

SUMMARY

It is an object of one or more embodiments herein to address these andother problems.

This and similar objects are achieved by a base station in a wirelesscommunication system configured to transmit user data to a wirelessdevice upon a first carrier. The base station comprises one or moreinterfaces configured to communicatively couple the base station to thewireless communication system. The base station also comprises one ormore transmitter processing circuits.

The one or more transmitter processing circuits are configured toidentify, from a set of transmission resources that is nominallyallocated for transmission of user data upon the first carrier, a subsetof transmission resources that is also nominally allocated fortransmission of a reference or control signal either by the base stationupon a second carrier or by a neighboring base station upon the firstcarrier. The one or more transmitter processing circuits are furtherconfigured to selectively transmit user data to the wireless device uponthe first carrier exclusive of the identified subset of transmissionresources.

In some embodiments, the one or more transmitter processing circuits areconfigured to selectively transmit user data by selectively mapping userdata upon the first carrier around the identified subset of transmissionresources. In this case, for example, the circuits generate an amount ofuser data to be transmitted to match an actual allocation oftransmission resources for user data upon the first carrier. This actualallocation accounts for the selective mapping of user data around theidentified subset of transmission resources.

In other embodiments, by contrast, the one or more transmitterprocessing circuits are configured to selectively transmit user data bypuncturing user data on the identified subset of transmission resources.In this case, for example, the one or more transmitter processingcircuits are further configured to generate an amount of user data to betransmitted to match the nominal allocation of transmission resourcesfor user data upon the first carrier. This nominal allocation does notaccount for the selective transmission of user data exclusive of theidentified subset of transmission resources.

Regardless, the one or more transmitter processing circuits in someembodiments are configured to transmit information to the wirelessdevice that explicitly or implicitly indicates this selectivetransmission of user data upon the first carrier exclusive of theidentified subset of transmission resources. In one embodiment, forexample, this information explicitly identifies at least a portion ofthe subset of transmission resources to the wireless device as nothaving user data for the wireless device. In this case, such informationmay comprise a reference signal muting pattern. Additionally oralternatively in another embodiment, the information explicitlyidentifies, for a given subframe, the first transmission resource fromthe start of the given subframe that is not included in the identifiedsubset of transmission resources.

Alternatively or additionally, the one or more transmitter processingcircuits in some embodiments are further configured to identify, fromthe set of transmission resources, a second subset of transmissionresources. This second subset is exclusively allocated for transmissionof user data upon the first carrier but is adjacent to transmissionresources nominally or actually allocated for transmission upon thesecond carrier. In this case, the one or more transmitter processingcircuits are configured to selectively transmit user data by selectivelytransmitting user data upon the first carrier also exclusive of theidentified second subset of transmission resources, to create one ormore virtual guard bands around the second carrier.

Note that, in at least some embodiments, the second carrier is a legacycarrier and the first carrier is a non-legacy carrier. In one suchembodiment, the one or more transmitter processing circuits areconfigured to dynamically discontinue selective transmission of userdata upon the first carrier responsive to a number of legacy wirelessdevices being served falling below a predefined threshold.

In another such embodiment, the reference or control signal is eithernot transmitted upon the first carrier or is transmitted upon the firstcarrier on a number of transmission resources that is smaller than anumber of transmission resources on which said reference or controlsignal is transmitted upon the second carrier.

Regardless, in one or more embodiments, transmission resources comprisetime-frequency resource elements. Moreover, the wireless communicationsystem is based on Long Term Evolution (LTE), the reference or controlsignal comprises common reference symbols (CRS) or a physical downlinkcontrol channel, and the user data is transmitted upon the first carrierover a physical downlink shared channel (PDSCH).

Embodiments herein also include a wireless device a wirelesscommunication system configured to receive user data from a base stationupon a first carrier. The wireless device comprises one or moreinterfaces configured to communicatively couple the wireless device tothe base station.

The wireless device also comprises one or more receiver processingcircuits. These circuits are configured to obtain information indicatingthat the base station is selectively transmitting user data to thewireless device upon the first carrier exclusive of a subset of a set oftransmission resources that is nominally allocated for user data uponthe first carrier. This subset of transmission resources is alsonominally allocated for transmission of a reference or control signaleither by the base station upon a second carrier or by a neighboringbase station upon the first carrier. The one or more receiver processingcircuits are also configured to, based on the obtained information,recover user data received upon the first carrier exclusive of thesubset of transmission resources.

In some embodiments, the one or more receiver processing circuits areconfigured to recover user data by demapping user data exclusive of thesubset of transmission resources. In other embodiments, by contrast, theone or more receiver processing circuits are configured to recover userdata by demapping user data from the set of transmission resourcesnominally allocated for user data and setting soft information fordecoding to indicate that user data demapped from the subset oftransmission resources is unreliable.

Regardless, in some embodiments, the obtained information explicitlyidentifies at least a portion of the subset of transmission resources tothe wireless device as not having user data for the wireless device. Inthis case, the obtained information may comprise for instance areference signal muting pattern. In other embodiments, though, theobtained information explicitly identifies, for a given subframe, thefirst transmission resource from the start of the subframe that is notincluded in the subset of transmission resources.

Note again that, in at least some embodiments, the second carrier is alegacy carrier and the first carrier is a non-legacy carrier. In onesuch embodiment, the reference or control signal is either nottransmitted upon the first carrier or is transmitted upon the firstcarrier on a number of transmission resources that is smaller than anumber of transmission resources on which said reference or controlsignal is transmitted upon the second carrier.

Regardless, in one or more embodiments, transmission resources comprisetime-frequency resource elements. Moreover, the wireless communicationsystem is based on Long Term Evolution (LTE), the reference or controlsignal comprises common reference symbols (CRS) or a physical downlinkcontrol channel, and the user data is transmitted upon the first carrierover a physical downlink shared channel (PDSCH).

Embodiments herein also include corresponding methods respectivelyimplemented by a base station and a wireless device according to any ofthe above described apparatus embodiments.

It is an advantage of one or more of these embodiments that interferenceis mitigated between (i) the transmission of user data by the basestation upon the first carrier; and (ii) the transmission of thereference or control signal either by the base station upon the secondcarrier or by the neighboring base station upon the first carrier.

Alternatively or additionally, an advantage of some embodiments is thefirst and second carriers may be deployed in an overlapping fashion insuch a way that conserves scarce transmission resources, enables theimmediate configuration of the first carrier as a non-legacy carrier,and simplifies the gradual phase out of the second carrier as a legacycarrier.

Alternatively or additionally, an advantage of some embodiments is thatthe base station enables the reference signal to be used by a wirelessdevice for synchronizing to the neighboring base station.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates the time-frequency grid for physical resources in aLong Term Evolution (LTE) wireless communication system.

FIG. 2 illustrates organization of LTE downlink transmissions into radioframes.

FIG. 3 illustrates a downlink LTE downlink subframe with controlsignaling transmitted in the first 3 OFDM symbols of the subframe.

FIG. 4 illustrates carrier aggregation with an example of 5 20 MHzcarriers being aggregated for a bandwidth of 100 MHz.

FIG. 5 shows the carrier structure of a so-called carrier type Aaccording to one or more embodiments.

FIG. 6 shows the carrier structure of a so-called carrier type Baccording to one or more embodiments.

FIG. 7 is a block diagram of a wireless communication system thatincludes a base station and a wireless device configured according toone or more embodiments.

FIG. 8 is a block diagram of a base station configured to transmit userdata to a wireless device upon a first carrier according to one or moreembodiments.

FIG. 9 is a block diagram of a wireless device configured to receiveuser data from a base station upon a first carrier according to one ormore embodiments.

FIG. 10 is a logic flow diagram of a method implemented by a basestation for transmitting user data to a wireless device upon a firstcarrier according to one or more embodiments.

FIG. 11 is a logic flow diagram of a method implemented by a wirelessdevice for receiving user data from a base station upon a first carrieraccording to one or more embodiments.

FIG. 12 shows carrier type A as transmitted centralized within carriertype B according to one or more embodiments from the perspective of abase station.

FIG. 13 shows carrier type A as seen from a legacy wireless deviceaccording to one or more embodiments.

FIG. 14 shows carrier type B in the presence of carrier type A as seenfrom a wireless device capable of receiving carrier type B.

FIG. 15 is a logic flow diagram of a method performed by a base stationaccording to one or more embodiments.

FIG. 16 is a logic flow diagram of a method performed by a wirelessdevice according to one or more embodiments.

FIG. 17 shows common reference symbols being transmitted on carrier typeB for synchronization purposes every fifth subframe and only on thecenter physical resource block pairs.

FIG. 18 illustrates a table defining how much guard band a wirelessdevice will assume according to one or more embodiments.

FIG. 19 shows the creation of a virtual guard band around carrier type Aaccording to one or more embodiments.

FIG. 20 shows selective mapping of PDSCH around certain CRS locationsaccording to one or more embodiments.

DETAILED DESCRIPTION

FIG. 7 illustrates a wireless communication system 10 according to oneor more embodiments. As shown in FIG. 7, the system 10 includes a radioaccess network (RAN) 12 and a core network (CN) 14. The RAN 12wirelessly connects one or more wireless devices 16 to the CN 14. Threedevices 16 are shown as devices 16A, 16B, and 16C. In at least someembodiments, devices 16A and 16C are non-legacy devices while device 16Bis a legacy device. A non-legacy device has capabilities that a legacydevice does not, in addition to or instead of a legacy device'scapabilities. Regardless, the CN 14 in turn connects the one or morewireless devices 16 to one or more external networks 18A, 18B. As shown,these one or more external networks 18A, 18B include a public switchedtelephone network (PSTN) 18A and a packet data network (PDN) 18B, suchas the Internet.

The RAN 12 more specifically includes a plurality of base stations 20,two of which are shown as base station 20A and base station 20B. Basestation 20A as shown is configured to transmit user data, e.g., thePDSCH/ePDCCH, to wireless device 16A upon a first carrier 22, e.g., ofcarrier type B. In some embodiments, base station 20A is furtherconfigured to transmit user data to wireless device 16A and/or 16B upona second carrier 24, e.g., of carrier type A. Also, in some embodiments,base station 20B neighbors base station 20A and is configured totransmit user data to wireless device 16C upon the first carrier 22.

FIG. 8 illustrates additional details of base station 20A according tosome embodiments where the base station 20A is configured to transmituser data to wireless device 16A upon the first carrier 22. The basestation 20A in this regard includes one or more interfaces 28, one ormore transmitter (TX) processing circuits 30, and one or more additionalprocessing circuits (not shown). The one or more interfaces 28 areconfigured to communicatively couple the base station 20A to thewireless communication system 10, e.g., to one or more other basestations 20 or network nodes via a network interface and to one or morewireless devices 16 via an air interface.

The one or more transmitter processing circuits 30 in some embodimentsfunctionally include a subset identifier circuit 32 and a transmissioncontroller circuit 34 configured to operate as described below.Additionally or alternatively, these circuits 32, 34 in otherembodiments are realized, implemented, or otherwise configured basedupon the execution of computer program instructions stored in memory 36or within another computer readable medium in the entity.

Regardless of particular implementation details, the one or moretransmitter processing circuits 30 are configured to identify, from aset of transmission resources that is nominally allocated fortransmission of user data upon the first carrier 22, a subset oftransmission resources that is also nominally allocated for transmissionof a reference or control signal either by the base station 20A upon thesecond carrier 24 or by the neighboring base station 20B upon the firstcarrier 22. The one or more transmitter processing circuits 30 are thenconfigured to selectively transmit user data to the wireless device 16Aupon the first carrier 22 exclusive of the identified subset oftransmission resources.

As used herein, a transmission resource is nominally allocated for aparticular transmission, e.g., for transmission of user data by the basestation upon the first carrier, or for transmission of a reference orcontrol signal either by the base station upon a second carrier or by aneighboring base station upon the first carrier, in the sense that theresource is designated or planned as being allocated for the particulartransmission, but may not actually be allocated in that way. Thus, atransmission resource's nominal allocation may vary from its actualallocation. In fact, selectively transmitting user data on the firstcarrier 22 exclusive of the identified subset of transmission resourcesas described above effectively changes the subset's actual allocation ascompared to its nominal allocation. Indeed, although the subset isnominally allocated for the transmission of user data upon the firstcarrier 22, selectively transmitting user data on the first carrier 22exclusive of that subset means that the subset is not actually allocatedfor the transmission of user data upon the first carrier 22.

With this understanding, note that the one or more transmitterprocessing circuits 30 identify the subset as being nominally allocatedfor both (i) the transmission of user data by the base station 20A uponthe first carrier 22; and (ii) the transmission of the reference orcontrol signal either by the base station 20A upon the second carrier 24or by the neighboring base station 20B upon the first carrier 22.Because the subset is nominally allocated for both of thesetransmissions, interference would occur between those transmissions,i.e., between the user data and the reference or control signal, if thesubset is actually allocated in accordance with the subset's nominalallocation. Selectively transmitting user data on the first carrier 22exclusive of the subset advantageously prevents or at least mitigatesthis interference. Indeed, this selective transmission dynamicallychanges the subset's actual allocation as compared to its nominalallocation so that the subset is not actually allocated for thetransmission of user data upon the first carrier 22.

The base station 20A being configured in this way proves advantageous ina number of contexts. Consider for instance embodiments where the subsetis nominally allocated for transmission of the reference or controlsignal by the base station 20A upon the second carrier 24. In this case,the first and second carriers 22, 24 employ overlapping transmissionresources. Indeed, this is dictated by the same subset of transmissionresources being nominally allocated for both the first and secondcarriers 22, 24. Regardless, user data is selectively transmitted uponthe first carrier 22 exclusive of the identified subset because thatuser data would have experienced interference on the subset due to thereference or control signal being transmitted upon the second carrier 24on that subset.

With interference to user data on the first carrier 22 able to bemitigated in this way, the first carrier 22 in at least some embodimentsis deployed as a non-legacy carrier, e.g., carrier type B, that overlapswith the second carrier 24 deployed as a legacy carrier, e.g., carriertype A. In this case, the first carrier 22 is deployed for use bywireless devices 16 with non-legacy capabilities, such as the wirelessdevices 16A and 16C, whereas the second carrier 24 is deployed for useby wireless devices 16 with legacy capabilities, such as the wirelessdevice 16B as well as wireless devices 16A and 16C in embodiments wherenon-legacy devices also have legacy capabilities. As one example, thereference or control signal is not transmitted upon the first carrier 22because it is not needed by devices 16, e.g., devices 16A and 16C, withnon-legacy capabilities, whereas the reference or control signal istransmitted upon the second carrier 24 because it is needed by devices16, e.g., device 16B, with only legacy capabilities. Alternatively, thereference of control signal may be transmitted upon the first carrier 22on a number of transmission resources that is smaller than a number oftransmission resources on which the reference or control signal istransmitted upon the second carrier 24. Regardless, deploying the firstand second carriers 22, 24 in this overlapping fashion advantageouslyconserves scarce transmission resources, enables the immediateconfiguration of the first carrier 22 as a non-legacy carrier, andsimplifies the gradual phase out of the second carrier 24 as a legacycarrier.

Next consider other embodiments where the subset is nominally allocatedfor transmission of the reference or control signal by the neighboringbase station 20B upon the first carrier 22. In this case, user data isselectively transmitted upon the first carrier 22 exclusive of theidentified subset because user data on the identified subset would haveinterfered with the reference or control signal being transmitted uponthe second carrier 24 on that subset. By mitigating interference to areference signal transmitted by the neighboring base station 20B on thefirst carrier 22, for example, the base station 20A enables thatreference signal to be used by wireless device 16C for synchronizing tothe neighboring base station 20B.

Irrespective of the particular context in which the base station'sconfiguration proves advantageous, the one or more transmitterprocessing circuits 30 in some embodiments are configured, e g byconfiguration of the subset identifier circuit 32, to identify thesubset by inspecting received control signaling or by retrieving staticor dynamic configuration information from memory 36. Moreover, while inat least some embodiments the one or more transmitter processingcircuits 30 or subset identifier circuit 32 is simply configured toidentify this subset as comprising resources on which user data is notto be transmitted, in other embodiments the one or more transmitterprocessing circuits 30 or subset identifier circuit 32 is configured tointelligently recognize that the transmission of user data on the subsetwould interfere or otherwise conflict with the transmission of thereference or control signal on the subset. In either case, of course,the one or more transmitter processing circuits 30 are configured, e gby configuration of the transmission controller circuit 34, to mitigatethat interference by selectively transmitting user data via the one ormore interfaces 28 upon the first carrier 22 exclusive of the identifiedsubset.

In at least some embodiments, for example, the one or more transmitterprocessing circuits 30 or transmission controller circuit 34 isconfigured to selectively transmit user data exclusive of the identifiedsubset by selectively mapping user data upon the first carrier 22 aroundthe identified subset of transmission resources. For instance, whereuser data on the first carrier 22 is transmitted over a PDSCH, the oneor more transmitter processing circuits 30 or transmission controllercircuit 34 may map that PDSCH around the identified subset. Regardless,the one or more transmitter processing circuits 30 or transmissioncontroller circuit 34 may proactively take this selective mapping intoaccount when initially generating the amount of user data to betransmitted. In this case, the one or more transmitter processingcircuits 30 or transmission controller circuit 34 may be configured togenerate the amount of user data to be transmitted to match the actualallocation of transmission resources for user data on the first carrier22, accounting for the selective mapping of user data around theidentified subset of resources. Such matching may entail, for instance,configuring the channel coding rate applicable to the user data to matchthe actual allocation of transmission resources for the data.

In other embodiments, by contrast, the one or more transmitterprocessing circuits 30 or transmission controller circuit 34 may beconfigured to generate the amount of user data to be transmitted tomatch the nominal (rather than the actual) allocation of transmissionresources for user data upon the first carrier 22, without accountingfor the selective transmission of user data exclusive of the identifiedsubset of resources. With the amount of user data generated in this way,i.e. to match the nominal allocation of transmission resources, the oneor more transmitter processing circuits 30 or transmission controllercircuit 34 may then be configured to implement the selectivetransmission of user data exclusive of the identified subset bypuncturing user data on the identified subset of resources. Thus, inthis case, the one or more transmitter processing circuits 30 ortransmission controller circuit 34 is configured to refrain fromtransmitting some of the user data previously generated, as necessary toavoid transmitting user data on the identified subset of resources. Thispuncturing proves to mitigate the above-mentioned interference withoutsubstantially affecting the device's receipt of the user data, given thechannel coding protection applied to the user data.

Because the one or more transmitter processing circuits 30 ortransmission controller circuit 34 is configured to selectively transmituser data to the wireless device 16A on less than the full set oftransmission resources nominally allocated for use on the first carrier22, the one or more transmitter processing circuits 30 or transmissioncontroller circuit 34 is configured to, in at least some embodiments,transmit information to the device 16A that explicitly or implicitlyindicates the selective nature of the data transmission. This way, thewireless device 16A may adjust or otherwise configure its receipt of theuser data to account for the fact that user data is not transmitted onthe full set of resources nominally allocated for the first carrier 22.

In at least some embodiments, for example, the one or more transmitterprocessing circuits 30 or transmission controller circuit 34 isconfigured to transmit, via the one or more interfaces 28, informationthat explicitly identifies the subset of resources to the wirelessdevice 16A as not having user data. As one example, where the subset ofresources is nominally allocated for transmission of a reference signal,either by the base station 20A on the second carrier 24 or by theneighboring base station 20B on the first carrier 22, those resourcesare structured in a repetitive pattern that can be indicated. The one ormore transmitter processing circuits 30 or transmission controllercircuit 34 may transmit such an indication as a muting pattern to informthe device 16A that transmissions on the subset of resources have beenmuted, i.e., transmitted with little or no power. Since in this examplethe subset of resources is nominally allocated for a reference signal,this muting pattern may resemble and be treated by the device 16A as areference signal muting pattern on the first carrier 22.

Additionally or alternatively in other embodiments, the one or moretransmitter processing circuits 30 or transmission controller circuit 34may transmit information that explicitly indicates the transmissionresources actually allocated for user data on the first carrier 22,accounting for the exclusion of the identified subset of resources. Forexample, in some embodiments, the information explicitly indicates aninitial transmission resource actually allocated for user data on thefirst carrier 22, with subsequent transmission resources actuallyallocated for user data being derivable by the wireless device 16A fromthat indication and earlier resources being included in the identifiedsubset.

Consider, for instance, embodiments where a transmission resourcecomprises a time-frequency resource, e.g., a resource element in LTE,and where the subset of resources is nominally allocated fortransmission of a control signal by the base station on a secondcarrier. In this case, the one or more transmitter processing circuits30 or subset identifier circuit 32 may determine that one or moretransmission resources at the start of a subframe are included in theidentified subset of resources, and are thus not to be actuallyallocated for user data transmission. The one or more transmitterprocessing circuits 30 determines, by subset identifier circuit 32, thefirst transmission resource that occurs next in the subframe, i.e., nextin time after the “control signal” resources, and signals, bytransmission controller circuit 34, that resource to the device 16A asbeing the start of user data in the subframe. That is, the one or moretransmitter processing circuits 30 transmit, via the one or moreinterfaces 28, information that explicitly identifies, for a givensubframe, the first transmission resource from the start of the givensubframe that is not included in the identified subset. In doing so, theone or more transmitter processing circuits 30 effectively exclude theresources in the identified subset from being considered as user data bythe device 16A.

In still other embodiments, the above techniques may be combined toexplicitly signal a portion of the subset of resources as not havinguser data, and to explicitly signal resources actually allocated foruser data on the first carrier 22 as a way to implicitly signal anotherportion of the subset. Such embodiments may prove useful, for instance,when one portion of the subset corresponds to resources allocated fortransmission of a reference signal, e.g., CRS, on the second carrier 24,and another portion of the subset corresponds to resources allocated fortransmission of a control signal, e.g., PDCCH, on the second carrier 24.

In at least some embodiments, however, wireless devices 16 configured toreceive this second carrier 24, such as legacy devices and in someembodiments also non-legacy devices, may operate under the assumptionthat the second carrier 24 is protected by a guard band. In this case,reception of the second carrier 24 may suffer if resources nominallyallocated for exclusive use by the first carrier 22 infringe on theassumed second carrier guard band, i.e., because they are adjacent toresources nominally allocated for use by both the first and secondcarriers 22, 24. Accordingly, the one or more transmitter processingcircuits 30 in some embodiments also identify, e g by subset identifiercircuit 32, from the set of transmission resources nominally allocatedfor transmission of user data upon the first carrier 22, a second subsetof transmission resources that are exclusively allocated fortransmissions upon the first carrier 22 but that are adjacent totransmission resources nominally allocated for transmission on thesecond carrier 24. Based on this identification, the one or moretransmitter processing circuits 30 selectively transmit, e g bytransmission controller circuit 34 via the one or more interfaces 28,user data on the first carrier 22 exclusive of both the first and secondsubsets of resources. This identification and selective transmissioneffectively creates a virtual guard band around the second carrier 24that is static regardless of whether the resources nominally allocatedfor transmission, e.g., of any type of signal or data, on the secondcarrier 24 are actually allocated.

Further sophistications in this regard therefore include the one or moretransmitter processing circuits 30 identifying a second subset ofresources that are adjacent to resources actually (as opposed to justnominally) allocated for transmission on the second carrier 24. In thiscase, selective transmission amounts to adjusting on which resourcesuser data is actually scheduled for transmission on the first carrier22. The effect of this may be that the virtual guard “band” created doesnot extend uniformly across the entire transmission bandwidth.

In view of the above modifications and variations, those skilled in theart will appreciate that a base station 20A herein may be staticallyconfigured to perform the identification and selective transmissiondescribed, without necessarily knowing that it is doing so in order tomitigate interference. That is, the base station 20A may not necessarilyknow that the identified subset of resources has been nominallyallocated for transmission of a reference or control signal either bythe base station 20A on a second carrier 24 or by a neighboring basestation 20B on the first carrier 22; the base station 20A may simplyunderstand that it is not to transmit user data on that subset ofresources.

In more sophisticated embodiments, by contrast, the base station 20Aindeed has this knowledge. In this case, the base station 20A mayidentify the subset of resources occasionally or periodically, in orderto dynamically adjust its selective transmission of user data as neededto mitigate interference under changing circumstances.

Consider, for instance, embodiments wherein the subset of resourcescorresponds to resources allocated for transmission of a reference orcontrol signal by the base station 20A on a second carrier 24, and wherethe second carrier 24 comprises a legacy carrier and the first carrier22 comprises a non-legacy carrier. In this case, the base station 20Amay be configured to dynamically adjust its selective transmission ofuser data responsive to the presence or absence of legacy devices, suchas wireless device 16B. For example, the base station 20A maydynamically discontinue selective transmission of user data on the firstcarrier 22, i.e. stop avoiding transmitting user data to the wirelessdevice 16A on the identified subset of transmission resources upon thefirst carrier 22, responsive to the number of legacy devices beingserved falling below a predefined threshold. In this way, theembodiments provide for a gradual phasing out of the legacy carrier 24as device population migrates from legacy to non-legacy, while at thesame time permitting immediate and resource efficient rolling out of thenon-legacy carrier 22. These same advantages may be realized of coursein the static embodiments mentioned above, but in that case wouldrequire external (e.g., manual) configuration.

In view of the above, those skilled in the art will also appreciatecounterpart configuration of a wireless device 16A herein. In thisregard, FIG. 9 depicts a wireless device 16A in a wireless communicationsystem 10 configured to receive user data from a base station 20A on afirst carrier 22.

According to FIG. 9, the wireless device 16A includes one or moreinterfaces 48, one or more receiver (RX) processing circuits 40, and oneor more additional processing circuits (not shown). The one or moreinterfaces 48 are configured to communicatively couple the device 16A tothe base station 20A, e.g., via an air interface.

The one or more receiver processing circuits 40 in some embodimentsfunctionally include an information obtaining circuit 42 and a datarecovery controller circuit 44 configured to operate as described below.Additionally or alternatively, these circuits 42, 44 in otherembodiments are realized, implemented, or otherwise configured basedupon the execution of computer program instructions stored in memory 46or within another computer readable medium in the entity.

Regardless of particular implementation details, the one or morereceiver processing circuits 40 are configured, e g by configuration ofthe information obtaining circuit 42, to obtain information indicatingthat the base station 20A is selectively transmitting user data to thewireless device 16A upon the first carrier 22 exclusive of a subset of aset of transmission resources that is nominally allocated for user dataupon the first carrier 22. This subset of transmission resources, asdiscussed above, is also nominally allocated for transmission of areference or control signal either by the base station 20A upon thesecond carrier 24 or by the neighboring base station 20B upon the firstcarrier 22. Obtaining information about this subset of resources mayentail inspecting control signaling received from the base station 20A,e.g., consistent with the various indications described above withrespect to the base station 20A, such as a muting pattern or initialuser data resource, or retrieving configuration information from memory46.

In any case, the one or more receiver processing circuits 40 are alsoconfigured, e g by configuration of the data recovery controller circuit44, to, based on the obtained information, recover user data receivedupon the first carrier 22 exclusive of the subset of transmissionresources. That is, even though the subset of transmission resources isnominally allocated for use by the first carrier 22, the wireless device16A does not actually recover user data from those resources.

In at least some embodiments, for example, recovering of user dataexclusive of the subset of resources entails demapping user data on thefirst carrier 22 exclusive of, i.e., around, that subset. For instance,where user data on the first carrier 22 is received over a PDSCH, thewireless device 16A demaps that PDSCH around the subset of resources.

In other embodiments, by contrast, recovering of user data exclusive ofthe subset of resources involves demapping user data on the firstcarrier 22 inclusive of the subset of resources, but setting softinformation for decoding to indicate that user data demapped from thesubset is unreliable. This setting of soft information may comprise, forinstance, setting soft symbol values for user data demapped from thesubset of resources to a value of 0.

In view of the above described configuration of the base station 20A andwireless device 16A, those skilled in the art will appreciate that thebase station 20A herein implements the method shown in FIG. 10 fortransmitting user data to the wireless device 16A upon the first carrier22, e.g., for transmitting the PDSCH/ePDCCH on carrier type B. As shownin FIG. 10, processing according to the method entails identifying, froma set of transmission resources nominally allocated for transmission ofuser data by the base station 20A upon the first carrier 22, a subset oftransmission resources that is also nominally allocated for transmissionof a reference or control signal, either by the base station 20A uponthe second carrier 24, e.g., on carrier type A, or by the neighboringbase station 20B upon the first carrier 22 (Block 100). The method thenincludes selectively transmitting user data to the wireless device 16Aon the first carrier 22 exclusive of the identified subset oftransmission resources (Block 110). That is, even though the subset oftransmission resources is nominally allocated for use by the firstcarrier 22, the base station 20A does not actually allocate or otherwiseuse those resources of the subset for user data (or for anything else).

Those skilled in the art will also appreciate counterpart processingperformed by a wireless device 16A herein. In this regard FIG. 11depicts processing performed by a wireless device 16A in a wirelesscommunication system 10 for receiving user data from the base station20A upon the first carrier 22.

As shown in FIG. 11, processing at the wireless device 16A includesobtaining information indicating that the base station 20A isselectively transmitting user data to the wireless device 16A on thefirst carrier 22 exclusive of a subset of a set of transmissionresources nominally allocated for user data upon the first carrier(Block 200). Consistent with the above, this subset of resources isnominally allocated for transmission of a reference or control signaleither by the base station 20A on the second carrier 24 or by theneighboring base station 20B on the first carrier 22. Obtaininginformation about this subset of resources may entail inspecting controlsignaling received from the base station 20A (e.g., consistent with thevarious indications described above with respect to the base station20A, such as a muting pattern or initial user data resource) orretrieving configuration information from memory 46.

In any case, processing continues, based on the obtained information,with recovering user data received upon the first carrier 22 exclusiveof the subset of transmission resources (Block 210). That is, eventhough the subset of transmission resources is nominally allocated foruse by the first carrier 22, the wireless device 16A does not actuallyrecover user data from those resources.

Those skilled in the art will also appreciate that no particularwireless communication technology or standard is required for practicingthe above embodiments. Nonetheless, in order to provide various concreteexamples, one or more embodiments will now be described in a contextwhere the wireless communication system 10 is based on Long TermEvolution (LTE). In these one or more LTE embodiments, the transmissionresources comprise time-frequency resource elements, the reference orcontrol signal comprises common reference symbols (CRS) or a physicaldownlink control channel, and user data is transmitted upon the firstcarrier 22 over a physical downlink shared channel (PDSCH). Moreover, inat least some of these embodiments, the first carrier 22 is thenon-legacy carrier, e g carrier type B, and the second carrier 24 is thelegacy carrier, e g carrier type A. Furthermore, using LTE terminology,wireless devices 16 are referred to as user equipments (UEs), and basestations 20 are referred to as enhanced NodeB's (eNBs).

In this context, it is a problem for an operator that would like todeploy a carrier of carrier type B in an existing band where a carriertype A is already deployed. The operators need a mechanism to handle thelarge amount of UE not being able to support carrier type B in theinitial stages and a migration solution when the balance between thenumber of terminals supporting carrier type A and B changes over time.

A similar problem exists for an operator that would like to deploy acarrier of carrier type B in neighboring cells. Indeed, in oneconfiguration of carrier type B, CRS for demodulation purpose are nottransmitted in every subframe but shortened or modified CRS may betransmitted in every fifth subframe or tenth slot to assist UE acquiringsynchronization with the additional carrier. With such a setup the reusefactor of the CRS for the purpose of synchronization is 6, i.e., 6shifts in frequency, which means that in a network with many cells therewill be CRS-to-CRS interference. Secondly it is further possible thatthe PDSCH/eCCH from a neigboring cell will interfere with the CRS, whereeCCH refers to the enhanced control channel (at the transport channellevel). These two examples of neighbor cell interference may limit theperformance of an additional carrier especially in a HetNet environmentwith many interfering sources.

Limiting Non-Legacy Carrier PDSCH Interference to Legacy Carrier CRS andPDCCH

One or more embodiments herein allow legacy UEs and newer UEs to coexiston a single carrier frequency. In one embodiment, the legacy and newercarrier types are transmitted in an overlapping fashion. The CRS areonly transmitted in the PRBs used by the legacy carrier. PDSCH mappingor UE decoding adapts to avoid interference of CRS to decoding of PDSCH.The start symbols used for the PDSCH are varied depending on whether thePRB pair is used by the legacy UEs in order to adapt to the presence oflegacy PDCCH transmissions. Transmission on PRB pairs is also adapted toeffectively provide guard bands around the part of the carrier that isused by legacy UEs.

More particularly, at a first stage when deploying a carrier type B, theeNB will transmit carrier type A at the same frequency in an overlappingfashion but with a smaller bandwidth than carrier type B. This willensure that both legacy UEs supporting only carrier type A and new UEssupporting both carrier type B and A or only carrier type B can accessthe network. New UE supporting both carrier type B and A or only carriertype B can gain the benefits of using carrier type B.

In the first embodiment, carrier types A and B are transmitted from theeNB on the same frequency in a partly overlapping manner. In FIG. 12,the case when carrier type A is transmitted centralized within carriertype B is illustrated from an eNB perspective. This example should notbe limiting but viewed as one possible implementation. This embodimentdistinguishes itself from known approaches because, in those approaches,carrier types A and B are not divided into different bandwidths parts.Instead, in embodiments herein, carrier types A and B are separatelydefined carriers that are transmitted on the same frequency.

From the UE perspective we have two points of view, either a UE thatreceives carrier type A or a UE that receives carrier type B. A UE thatreceives carrier type A, i.e. a legacy UE, is not aware that carriertype B exists and hence it will observe carrier type A as only beingdeployed without any carrier type B present. FIG. 13 illustrates carriertype A as seen from a legacy UE.

A UE that is receiving carrier type B will however need to be aware insome manner that carrier type A exists in the middle of the allocatedspectrum. This is to ensure that such UE knows which REs carry itsPDSCH/eCCH. The key aspect that such a UE needs to know is the REs onwhich CRS are transmitted upon carrier type A because the PDSCH and eCCHbits are not transmitted on these REs upon carrier type B. FIG. 14illustrates carrier type B in the presence of a carrier type A as seenfrom a UE capable of receiving carrier type B.

In a second embodiment the eNB configures the UE either by dedicatedsignal or broadcast information to make known which REs are used for CRSon carrier type A, i.e. a CRS muting pattern. FIG. 15 illustrates thisas a flow chart of broadcasting the CRS muting pattern in the basestation. Correspondingly, FIG. 16 illustrates this as a flow chart of aterminal receiving information about muted CRS in the base station.

The UE and eNB can use this information in two different ways.

In a first option the eNB maps the PDSCH around the muted REs whentransmitting PDSCH/eCCH to a UE. When receiving the PDSCH or ePDCCH,ePHICH, the UE will use the information that some REs are muted by theeNB and correspondingly adjusts its demapping of the PDSCH taking intoaccount that the eNB did not map PDSCH to certain REs.

In a second approach the PDSCH/eCCH bits in total amount is generatedwithout considering whether there are some REs that should not containany PDSCH/eCCH. The mapping of the PDSCH/eCCH may be done in such a waythat the eNB when it comes to muted REs skips to map out thiscorresponding symbol on that RE, but forwards its counter to the nextsymbol for placement in the next REs. That is, some of the PDSCH/eCCHbits are punctured and never transmitted by the eNB. Otherimplementations that create a punctured PDSCH/eCCH realize the sameembodiment. The UE will demap all symbols not considering that certainsymbols do not contain either PDSCH or eCCH. For the UE configured withthe muting pattern by the eNB it will be able to enhance its decodingperformance by setting the soft value symbols corresponding to muted REsto 0 or to a similar value that indicates that the soft values derivedfrom these symbols are very unreliable.

In a third embodiment the eNB configures the UE either in a UE-specificmanner or through broadcast with the starting OFDM symbol in a subframeof PDSCH and/or eCCH configured differently for different PRB pairs.This is to enable a UE receiving PDSCH or eCCH from carrier type B totake into account the presence of PDCCH/PHICH/PCFICH on carrier type A.Similar to in embodiment 2, this may be done in two ways consideringboth the eNB and UE implementations. The signaling scheme may forexample be turned into practice as follows. The UE by default assumesthat the PDSCH/eCCH maps from the first OFDM symbol and the eNB mayadditionally indicate through signaling a set of the PRB pairs that hasa different starting OFDM symbol for PDSCH/eCCH.

In a first option, the eNB selects the first OFDM symbol to map thePDSCH/eCCH on carrier type B for a certain PRB pair as part of theconfiguration in the UE for the first set of PRB pairs and another firstOFDM symbol for a second set of PRB pairs. The configured value in theterminal may for example be OFDM symbol 1, 2, 3 or 4. The UE whendemapping the PDSCH/eCCH assumes the same RE mapping as the eNB. Thestarting OFDM symbol of PDSCH/eCCH may also be derived by othermechanisms by the UE for example reading PCFICH, ePCFICH or a MACcontrol element.

In a second option the eNB maps out PDSCH/eCCH for carrier type B fromthe first OFDM symbol assuming that PDCCH/PCFICH/PHICH from the carriertype A does not exist. If some REs contain both PDSCH/eCCH from carriertype B and PDCCH/PHICH/PCFICH from carrier type A, the eNB will transmitPDCCH/PHICH/PCFICH belonging to carrier type A in those REs. The UE maybe configured with the knowledge that eNB may transmit somethingdifferent than the PDSCH/eCCH in the first few beginning OFDM symbolswithin some of its PRB pairs. These signaled values may for example be1, 2, 3 or 4. Similar as in the first option the UE can retrieve thisknowledge by reading PCFICH, ePCFICH or a MAC control element. The UEmay use this information in its receiver to set the corresponding softvalue that are de-mapped from the first OFDM symbols to the value 0 orto a similar value that indicates that the soft value derived there isvery unreliable.

It is up to the UE implementation to figure out if PDSCH/eCCH areactually transmitted in earlier OFDM symbols as configured and to usethese symbols for improved reception. A baseline UE would only followthe eNB configuration. That is, a simple UE would only monitor thelength of PDCCH by detecting for example PCFICH on its own carrier.

Assuming a network deployment where several eNBs transmit both carriertype A and carrier type B according to FIG. 17 (described below),together with UEs operating that can only receive carrier type A, UEsdesigned only to receive carrier type A will suffer a significantperformance degradation if carrier type A and carrier type B aretransmitted as in FIG. 17, because the filter designed in such a UEassumes the presence of guard band at each end of the system bandwidth.If the guard band is not present, the UE will receive its desireddownlink signal as well as transmissions from neighboring cells in theform of increased interference. How much guard band the UE will assumeis defined in TS 36.101 V10.5.0 in table 5.6-1. The guard band isdefined by taking the difference between the channel bandwidth and thetransmission bandwidth configuration. For completeness the same table isalso replicated as Table 1 in FIG. 18, together with the transmissionbandwidth.

In a fourth embodiment, the eNB needs to have no or reduced schedulingactivity in PRB pairs located in frequency close to carrier type A butwithin carrier type B, particularly in those PRB pairs currentlyscheduled within carrier A close to the carrier A edge. This isillustrated in FIG. 19, where a virtual guard band has been introducedby the eNB by reducing the scheduling activity on the specific PRB pairsthat are next to carrier type A. This is to create virtual guard band(s)to protect the UEs that are only receiving carrier type A from receivingadditional interference.

The creating of virtual guard bands can be done in two ways. In bothways, the PRB pairs in the virtual guard band are excluded from thetransmission bandwidth. In the first option, the PRB pairs in thevirtual guard band do not have RB indexing numbers. Since they are noteven accessible by the PDSCH resource allocation or ePDCCHconfiguration, they cannot be scheduled or used and no signals aretransmitted there.

In the second possibility of creating virtual guard bands, PDSCH is notscheduled or is reduced in these guard bands. Furthermore, CSI-RStransmission may be transmitted with zero power (muted) in this guardbands to protect UEs receiving only carrier type A.

The embodiments outlined here thus makes a transition between legacy andnew carrier types smoother as it will enable both legacy UEs and new UEsable to access the spectrum during a given time frame. At the same timethe solution provides the new UEs capable of receiving a new carriertype to be tested early with its unique functionality to ensure thatthey can be deployed as early as possible in the network.

Limiting Non-Legacy Carrier PDSCH Interference to Non-Legacy Carrier CRSin Neighboring Cell

One or more other embodiments herein limit the extent to which thePDSCH/eCCH from one cell, or one base station, will interfere with theCRS of another cell, or another base station. In particular, the eNBtransmitting in the network should avoid mapping PDSCH on to REs thatare used for CRS for synchronization purposes in another eNB. Forexample, in some embodiments, muted CRS patterns are used at the eNB toavoid transmission of PDSCH on REs used by other eNBs for CRS in orderto avoid PDSCH to CRS interference that may degrade synchronizationcapabilities. Muted CRS may be used to occupy entire OFDM symbols orthey could be spread across subframes in time. A combination of bothtechniques may also be used to ensure a high degree of reuse for the CRSused for synchronization.

In a first embodiment the eNB does not map any PDSCH toward any OFDMsymbol containing CRS for synchronization purposes. This will aid UEs inneighboring cells in performing synchronization as they will not see anyPDSCH-to-CRS interference. The limit on which OFDM symbols to map PDSCHtoward can also be amended by only applying the limit to certain numberof PRB pairs, typically the same PRB pairs that also contain CRS forsynchronization purposes. FIG. 17 illustrates the case when CRStransmitted for synchronization purpose are transmitted every fifthsubframe and only occupy the center PRB pairs. In the example in thefigure PDSCH are not mapped to the OFDM symbols in the PRBs whichcontains the CRS for synchronization purposes.

In a second embodiment a further frequency reuse is created by mutingCRS locations in other OFDM symbols as well, this in order to moreuniquely be able to configure each eNB so that there will be very smallprobability that a UE will see CRS-to-CRS interference. An example ofthis is shown in FIG. 20 where certain CRS locations do not have anyPDSCH mapped on to it. That is, muted CRS positions are mapped out intime in FIG. 20.

Embodiments 1 and 2 can further also be combined and performed togetherat the same time.

When performing embodiment 1 and 2, the actual PDSCH/eCCH mapping at theeNB can be done in two different ways. In a first method the PDSCH/eCCHbits in total amount are generated assuming that certain REs will notcontain any PDSCH/eCCH. The mapping is essentially done around the holescreated by the muting pattern. In a second method the PDSCH/eCCH bits intotal amount are generated without considering whether there are someREs that should not contain any PDSCH/eCCH. The mapping of thePDSCH/eCCH can be done so that the eNB when it comes to muted REs skipsthe mapping out of this corresponding symbol on that RE, but forwardsits counter to the next symbol for placement in the next REs. That is,some of the PDSCH/eCCH bits are punctured and never transmitted by theeNB. Other implementations that create a punctured PDSCH/eCCH realizethe same embodiment.

In the UE receiver the UE will for the first method consider in itsdemapping that certain REs do not contain any PDSCH/eCCH, i.e. the UEwill use a different demapping function of symbols if CRS muting patternis configured as compared to the absence of CRS muting patterns. For thesecond method the UE will demap all symbols not considering that certainsymbols do not contain either PDSCH or eCCH. The UE will however whenconfigured with the muting pattern by the eNB be able to enhance itsdecoding performance by setting the soft value symbols corresponding tomuted REs to 0 or to a similar value that indicates that the soft valuederived there is very unreliable.

Irrespective of whether described in an LTE context or not, note thatthe term “subset” is used herein in its general sense to refer to a partor portion of a larger set. This contrasts with the purely mathematicalsense of the term in which a subset may be the same as the set. Inmathematical terms, a “subset” as used herein is really a “propersubset.”

The present invention may, of course, be carried out in other specificways than those herein set forth without departing from the scope andessential characteristics of the invention. The present embodiments are,therefore, to be considered in all respects as illustrative and notrestrictive.

What is claimed is:
 1. A base station for a wireless communicationsystem configured to transmit user data to a wireless device upon afirst carrier, the base station comprising: one or more interfacesconfigured to communicatively couple the base station to the wirelesscommunication system, and one or more processing circuits configured to:identify, from a set of transmission resources nominally allocated fortransmission of user data by the base station upon the first carrier, asubset of transmission resources also nominally allocated fortransmission of a reference signal upon a second carrier; andselectively transmit the user data to the wireless device upon the firstcarrier exclusive of the identified subset of transmission resources,wherein the first carrier is of a type upon which said reference signalis not transmitted.
 2. The base station of claim 1, wherein said one ormore processing circuits are configured to selectively transmit the userdata by selectively mapping the user data upon the first carrier aroundthe identified subset of transmission resources.
 3. The base station ofclaim 2, wherein said one or more processing circuits are furtherconfigured to: generate an amount of user data to be transmitted tomatch an actual allocation of transmission resources for user data uponthe first carrier; wherein the actual allocation accounts for theselective mapping of the user data around the identified subset oftransmission resources.
 4. The base station of claim 1, wherein said oneor more processing circuits are configured to selectively transmit theuser data by puncturing user data from the identified subset oftransmission resources.
 5. The base station of claim 4, wherein said oneor more processing circuits are further configured to: generate anamount of user data to be transmitted to match the nominal allocation oftransmission resources for user data upon the first carrier; wherein thenominal allocation does not account for the selective transmission ofuser data exclusive of the identified subset of transmission resources.6. The base station of claim 1, wherein the one or more processingcircuits are further configured to transmit information to the wirelessdevice that explicitly or implicitly indicates selective transmission ofthe user data upon the first carrier exclusive of the identified subsetof transmission resources.
 7. The base station of claim 6, wherein theinformation explicitly identifies at least a portion of the subset oftransmission resources to the wireless device as not having user datafor the wireless device.
 8. The base station of claim 7, wherein theinformation comprises a reference signal muting pattern.
 9. The basestation of claim 6, wherein the information explicitly identifies, for agiven subframe, a first transmission resource from a start of the givensubframe that is not included in the identified subset of transmissionresources.
 10. The base station of claim 1, wherein the one or moreprocessing circuits are further configured to: identify, from the set oftransmission resources, a second subset of transmission resources thatis exclusively allocated for transmission of user data upon the firstcarrier but that is adjacent to transmission resources nominally oractually allocated for transmission upon the second carrier; selectivelytransmit the user data by selectively transmitting the user data uponthe first carrier also exclusive of the identified second subset oftransmission resources to create one or more virtual guard bands aroundthe second carrier.
 11. The base station of claim 1, wherein the secondcarrier comprises a legacy carrier and the first carrier comprises anon-legacy carrier, and wherein the one or more processing circuits arefurther configured to dynamically discontinue selective transmission ofthe user data upon the first carrier responsive to a number of legacywireless devices being served falling below a predefined threshold. 12.The base station of claim 1, wherein the second carrier comprises alegacy carrier and the first carrier comprises a non-legacy carrier. 13.The base station of claim 1, wherein the user data is selectivelytransmitted to the wireless device upon the first carrier over aphysical downlink shared channel.
 14. A wireless device for a wirelesscommunication system configured to receive user data from a base stationupon a first carrier, the wireless device comprising: one or moreinterfaces configured to communicatively couple the wireless device tothe base station; one or more processing circuits configured to: obtaininformation indicating that the base station is selectively transmittingthe user data to the wireless device upon the first carrier exclusive ofa subset of a set of transmission resources nominally allocated for userdata upon the first carrier, wherein the subset of transmissionresources is also nominally allocated for transmission of a referencesignal upon a second carrier; and based on the obtained information,recover the user data received upon the first carrier exclusive of thesubset of transmission resources, wherein the first carrier is of a typeupon which said reference signal is not transmitted.
 15. The wirelessdevice of claim 14, wherein the one or more processing circuits areconfigured to recover the user data by demapping the user data exclusiveof the subset of transmission resources.
 16. The wireless device ofclaim 14, wherein the one or more processing circuits are configured torecover the user data by: demapping the user data from the set oftransmission resources nominally allocated for user data; and settingsoft information for decoding to indicate that the user data demappedfrom the subset of transmission resources is unreliable.
 17. Thewireless device of claim 14, wherein the obtained information explicitlyidentifies at least a portion of the subset of the set of transmissionresources to the wireless device as not having user data for thewireless device.
 18. The wireless device of claim 17, wherein theobtained information comprises a reference signal muting pattern. 19.The wireless device of claim 14, wherein the obtained informationexplicitly identifies, for a given subframe, a first transmissionresource from a start of the subframe that is not included in the subsetof the set of transmission resources.
 20. The wireless device of claim14, wherein the second carrier comprises a legacy carrier and the firstcarrier comprises a non-legacy carrier.
 21. The wireless device of claim14, wherein the user data is selectively transmitted upon the firstcarrier over a physical downlink shared channel.
 22. A methodimplemented by a base station in a wireless communication system fortransmitting user data to a wireless device upon a first carrier, themethod comprising: identifying, from a set of transmission resourcesnominally allocated for transmission of user data by the base stationupon the first carrier, a subset of transmission resources alsonominally allocated for transmission of a reference signal upon a secondcarrier; and selectively transmitting the user data to the wirelessdevice upon the first carrier exclusive of the identified subset oftransmission resources, wherein the first carrier is of a type uponwhich said reference signal is not transmitted.
 23. A method implementedby a wireless device in a wireless communication system for receivinguser data from a base station upon a first carrier, the methodcomprising: obtaining information indicating that the base station isselectively transmitting the user data to the wireless device upon thefirst carrier exclusive of a subset of a set of transmission resourcesnominally allocated for user data upon the first carrier, wherein thesubset of the set of transmission resources is also nominally allocatedfor transmission of a reference signal upon a second carrier; and basedon the obtained information, recovering the user data received upon thefirst carrier exclusive of the subset of transmission resources, whereinthe first carrier is of a type upon which said reference signal is nottransmitted.